Issue 19, 2021

Planar hydrodynamic traps and buried channels for bead and cell trapping and releasing

Abstract

We present a novel concept for the controlled trapping and releasing of beads and cells in a PDMS microfluidic channel without obstacles present around the particle or in the channel. The trapping principle relies on a two-level microfluidic configuration: a top main PDMS channel interconnected to a buried glass microchannel using round vias. As the fluidic resistances rule the way the liquid flows inside the channels, particles located in the streamlines passing inside the buried level are immobilized by the round via with a smaller diameter, leaving the object motionless in the upper PDMS channel. The particle is maintained by the difference of pressure established across its interface and acts as an infinite fluidic resistance, virtually cancelling the subsequent buried fluidic path. The pressure is controlled at the outlet of the buried path and three modes of operation of a trap are defined: idle, trapping and releasing. The pressure conditions for each mode are defined based on the hydraulic–electrical circuit equivalence. The trapping of polystyrene beads in a compact array of 522 parallel traps controlled by a single pressure was demonstrated with a trapping efficiency of 94%. Pressure conditions necessary to safely trap cells in holes of different diameters were determined and demonstrated in an array of 25 traps, establishing the design and operation rules for the use of planar hydrodynamic traps for biological assays.

Graphical abstract: Planar hydrodynamic traps and buried channels for bead and cell trapping and releasing

Article information

Article type
Paper
Submitted
25 May 2021
Accepted
25 Aug 2021
First published
14 Sep 2021
This article is Open Access
Creative Commons BY-NC license

Lab Chip, 2021,21, 3686-3694

Planar hydrodynamic traps and buried channels for bead and cell trapping and releasing

C. Lipp, K. Uning, J. Cottet, D. Migliozzi, A. Bertsch and P. Renaud, Lab Chip, 2021, 21, 3686 DOI: 10.1039/D1LC00463H

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